Matrix effect on surface-catalyzed photolysis of nitric acid

Photolysis rate constant of HNO 3 on the surface (HNO 3(s) ) has been found to be enhanced by 1–4 orders of magnitude from that of gaseous HNO 3 , with HONO and NO 2 as the main products. Such Re-NOx-ification pathway extends the apparent lifetime of reactive nitrogen species and modifies the atmosp...

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Bibliographic Details
Published in:Scientific reports 2019-03, Vol.9 (1), p.4351, Article 4351
Main Authors: Ye, Chunxiang, Zhang, Ning, Gao, Honglian, Zhou, Xianliang
Format: Article
Language:English
Subjects:
704/172/169/824
704/172/169/896
Catalysis
Humanities and Social Sciences
multidisciplinary
Nitric acid
Nitrogen dioxide
Organic compounds
Oxidation
Photochemicals
Photolysis
Photosensitization
Reactive nitrogen species
Science
Science (multidisciplinary)
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Summary:Photolysis rate constant of HNO 3 on the surface (HNO 3(s) ) has been found to be enhanced by 1–4 orders of magnitude from that of gaseous HNO 3 , with HONO and NO 2 as the main products. Such Re-NOx-ification pathway extends the apparent lifetime of reactive nitrogen species and modifies the atmospheric oxidative capacity along its long-rang transport. Despite of its importance, the detailed kinetics and mechanisms of HNO 3(s) photolysis are still not clear. Surface film of HNO 3 and organic compounds is ubiquitous in the environment and imposes matrix effect on HNO 3(s) photolysis. Here we studied photolysis of HNO 3 on Pyrex glass in a photochemical flow reactor over a wide range of HNO 3 surface density ( D HNO3 ) with or without the presence of model organic compounds. The photolysis rate constant of HNO 3(s) varied with D HNO3 and surface-catalysis mechanism was proposed. Organic compounds further enhance the photolysis rate constant by up to one order of magnitude via both photosensitization and H-donating reaction. The H-donating reaction enhances as well the secondary HONO yield from reaction between the primary product NO 2 and adjacent H-donor, and thus increases the HONO/NO 2 production ratio. Finally, detailed mechanisms involving surface-catalyisis, photosensitization and H-donating reactions was integrated.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-018-37973-x